Summary Pluripotent stem cells (ES and iPS cells) have the ability to self-renew and to differentiate into multiple lineages in vitro. This makes these cells a powerful tool to study early embryonic developmental pathways and to generate specific cell populations for regenerative medicine and disease investigation. Our research group has pioneered methods to derive large quantities of skeletal myogenic progenitor cells from mouse and human pluripotent ES and iPS cells. Upon transplantation into dystrophic mice, these progenitors are not only able to generate new functional myofibers, but also to seed the satellite cell compartment, thus providing long-term regeneration. With prior NIH support, we defined the molecular signature of in vitro-generated PSC-derived myogenic progenitors by comparing their transcriptome profiles to those of primary skeletal myogenic progenitors isolated at different developmental stages. Our findings revealed that PSC-derived myogenic progenitors possess a molecular signature similar to embryonic/fetal myoblasts. Paradoxically however, they differ functionally from fetal myoblasts, as PSC-derived myogenic progenitors show much superior myofiber engraftment and ability to seed the satellite cell niche, respond to multiple re-injuries and contribute to long-term regeneration. These results led us to hypothesize that exposure to the adult host skeletal muscle environment may induce molecular changes in transplanted cells. We found this to be the case as transcriptome analysis of PSC-derived mononuclear cells (MNCs) re-isolated after engraftment revealed a shift in molecular signature from embryonic/fetal towards neonatal/adult stages. In this renewal application we propose studies to understand i) the interaction and molecular cues provided by the adult niche that favor the in vivo maturation of PSC-derived myogenic progenitors, ii) the role of post-transcriptional regulation in this process, and iii) the dynamics of engraftment and the quiescence status of specific donor-derived sub-fractions.